SU1341210A1 - Method of melting steel from solid charge in converter - Google Patents

Description

113

The invention relates to ferrous metallurgy, namely to the oxygen-converter method of steel smelting.

The purpose of the invention is to improve the performance of the converter and the durability of its lining.

It has been established by research that the capacity of the converter and the strength of the lining depend on the heating mode of scrap, its filling method and solid energy carrier, the ratio between the top and bottom costs, and the oxidation potential to blow.

The filling of large portions of scrap into the converter (greater than 0.7 working volume) complicates the heating process, especially the use of upper tuyere burners. There are large losses of oxygen and fuel from waste - by shim gases due to the high location practically at the cut of the tuyere neck.

The experience of industrial converters shows that the bulk of the scrap metal used in converter production has a bulk density less than 1.0, which, when it is processed in a converter without liquid iron, significantly (by 30-50%) reduces the converter draft and its productivity .

In addition, with a significant filling of the converter cavity with metal breakage and in connection with this inefficient top heating, the charge hangs due to heating and melting it in the lower layers, free bridges are made of welded scrap metal. Therefore, it is advisable to load scrap metal with parts, with subsequent heating of each scrap part, which allows the converter to have a volume free from scrap metal and, therefore, conditions for its efficient heating using top heating.

It has been established that it is most efficient to load scrap in three portions, and the first portion should occupy about 50-60% of the total scrap consumption, loading less than 50% is impractical, since the converter's performance decreases due to a significant increase in the mass of subsequent batches of scrap. In addition, the decrease in the mass of the first portion when

0

5 o

y .ts

0

O2

leads to a significant reduction in fuel utilization, because filter bed height is reduced. The mass of the second portion of scrap metal is determined by the conditions for heating the first portion, by reducing the level of scrap in the converter, i.e. the amount of free workspace converter. Studies have shown that 48-52% of the remaining scrap is optimal. Loading less than 48% of the remaining scrap is impractical because the weight of the third part of the scrap increases significantly, which leads to an extension of the heating process of the entire scrap, and in the case of using scrap with a low bulk weight, the filling time is prolonged, which reduces converter productivity.

Increasing the mass of the second portion of scrap to more than 52% significantly increases the level of scrap in the converter, reduces the free volume of the working space to less than the optimal values (less than 0.3 working volume), which reduces the converter's performance, as noted above.

The loading of solid energy carrier in two portions in the amount of 30-35% of the scrap set before loading and the rest amount after the loading of the entire scrap metal improves the combustion process during heating and also reduces the lining wear in the bottom part of the converter.

Loading a single-portion solid energy carrier leads to a significant local placement, which complicates its combustion and reduces the converter's performance, an increase in the mass of the first solid energy carrier, more than 35% of which is loaded to the bottom and more than 70% to the scrap surface, also leads to this disadvantage.

When the amount of solid energy carrier decreases below 30% of the specified load loaded to the bottom, the heating efficiency of the lower layers of the charge decreases, which reduces the converter's moisture content, and the lining wear increases due to the effect of iron oxides.

It was established experimentally that the durability of the converter lining, its performance depends on the mode

ma entering oxygen during scrap heating,

The supply of oxygen-containing gas with an excess of oxygen of more than 50% of stoichiometric leads to a significant over-oxidation of scrap, which reduces the durability of the lining, while the rate of reduction of solid energy carrier does not increase. When reducing the excess oxygen below 40% of the stoichiometric, there is a decrease in converter performance, since the rate of burning of solid energy is slowed down.

The change in the ratio of oxygen supplied to heating and blowing is related to the nature of the combustion of solid energy carrier during these periods of melting.

It has been established that the maximum converter capacity is achieved by supplying oxygen from the bottom in the first heating stage and during purging 1.5-2.0 times lower than that from above, and is 0.9-1.0 in the second heating stage.

An increase in the ratio of oxygen consumption from below and above by more than 2.0 times in the first heating stage during blowdown reduces the capacity of the converter, and due to poor oxygen absorption during its upper supply, the lining resistance in the upper part of the converter decreases.

A decrease in this ratio of less than 1.5 leads to a significant increase in the oxidation of scrap in the lower part of the converter due to the delay in the ignition of solid energy carrier, which at a volume of 0.72 m was loaded with 19.5 kg

coal grade AC (32.5% of total consumption), 432 kg of scrap metal with a heavy weight of 1.0 t / m. For 3 min, the mixture was heated and the lining was reduced.

After loading the second batch of scrap metal, conditions are created.

when the burning rate of the solid energy of oxygen and natural gas of the lower carrier reaches maximum values, it is advisable to increase the oxygen consumption from the bottom to increase the converter capacity, i.e. reduce the ratio of oxygen consumption from below and above. However, a decrease in this ratio less than 0.9 does not lead to the intensification of the process of burning solid energy carrier, an increase in the loss of iron and a decrease in the durability of the lining are observed. At a ratio greater than 1.0, on the one hand, the rate of oxidation of the solid energy decreases.

0

five

0

five

0 g

The bodies in the lower layers of the charge, on the other hand, have a loss of oxygen supplied through the upper lance with waste gases, which, in aggregate, reduces the converter capacity and the durability of the lining.

The duration of heating the scrap in the first and second stages is determined by the conditions of shrinkage (lowering) of the scrap in the converter, which, in turn, is related to the temperature of the scrap. The latter depends on the amount of heat introduced into the mixture during combustion of fuel and .. solid energy carrier.

Reducing the oxygen consumption for heating the charge below - I5% of the total smelting in the first and second stages does not ensure sufficient heating of the scrap and its shrinkage, which during the loading of the next batch of scrap leads to a significant deterioration of the conditions for heating the charge with the upper tuyere burner, which reduces converter performance.

Increasing this consumption by more than 25% is associated with significant overheating of scrap and lowering it. This reduces KIT fuel, because the height of the filter layer is reduced, its temperature and the heat content of the exhaust gases increase and, consequently, the converter capacity decreases.

Conducted a series of tests on the proposed technology. The results of the tests are shown in the table.

Example. In the converter with rabose and top. Oxygen consumption from below 1, from above - 1.75 m / min (cost ratio was 1: 2), natural gas consumption from below

0.345, above - 0.69, which is the oxygen consumption by 45% more than stoichiometric.

Then, 240 kg of scrap metal with a total weight of 1.1 t / m was piled up and the mixture was heated for 8 minutes by supplying oxygen and natural gas from the bottom and top with equal costs. The consumption of oxygen is 1.5 m / min, the consumption of natural gas is 0.52.

513412

The cost ratio below and above 1: 1. Then another 240 kg of scrap metal and 40.5 kg of coal AC (67.5%) were loaded and for 24 minutes a oxygen bath was blown from the bottom with a flow rate of 1.0, from the top - 2.0. The consumption of natural gas was gradually reduced, and after 14 minutes and until the end of the purge, the consumption of natural gas to the bottom tuyeres was 0.1, and the last 6 minutes from above was supplied only with oxygen. Duration Melting 40 min.

6

The total oxygen consumption was 120 m. Steel yield 848 kg. Converter capacity 1272 kg / h.

Indicators of heats with the boundary values of the parameters, above and below them, as well as the prototype are presented in the table.

The use of the proposed technology as compared to the base technology allows the converter to increase productivity by 20% and reduce the consumption of refractories by 1.8 kg per ton of steel.

Editor M. Tsitkina

Compiled by M.Pribavkin Tehred M.Hodanich

Order 4402/31

Circulation 549Subscribe

VNIIPI USSR State Committee

on de lamas of inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5

Production and printing enterprise, Uzhgorod, Projecto st., 4

Proofreader L. Pilipenko

Claims (1)

METHOD OF MELTING STEEL FROM A SOLID CHARGE IN THE CONVERTER, including layer-by-layer loading of scrap metal and solid energy carrier, multi-stage heating, melting of the charge by supplying oxygen-containing gas and fuel from above and below to produce finished steel, characterized in that, in order to increase the productivity of the converter and lining resistance, 30-35% of solid energy carrier and 50-60% of the total scrap metal consumption are loaded onto the bottom of the converter and heating is performed at a ratio of oxygen consumption from bottom to top of 1: (1.5-2.0), then 48-52% o scrap metal and reheat at a ratio of oxygen consumption of 1: (0.9-1.0), and the total oxygen consumption per g heating of each portion of the charge is 15-25% of the total consumption for melting, and then load the remaining scrap metal, energy carrier and purge the bath to obtain finished steel. Utztwt'ts